//===-- Args.cpp ------------------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/lldb-python.h" // C Includes #include <getopt.h> #include <cstdlib> // C++ Includes // Other libraries and framework includes // Project includes #include "lldb/Interpreter/Args.h" #include "lldb/Core/Stream.h" #include "lldb/Core/StreamFile.h" #include "lldb/Core/StreamString.h" #include "lldb/DataFormatters/FormatManager.h" #include "lldb/Interpreter/Options.h" #include "lldb/Interpreter/CommandReturnObject.h" #include "lldb/Target/Process.h" //#include "lldb/Target/RegisterContext.h" #include "lldb/Target/StackFrame.h" #include "lldb/Target/Target.h" //#include "lldb/Target/Thread.h" using namespace lldb; using namespace lldb_private; //---------------------------------------------------------------------- // Args constructor //---------------------------------------------------------------------- Args::Args (const char *command) : m_args(), m_argv(), m_args_quote_char() { if (command) SetCommandString (command); } Args::Args (const char *command, size_t len) : m_args(), m_argv(), m_args_quote_char() { if (command && len) SetCommandString (command, len); } //---------------------------------------------------------------------- // We have to be very careful on the copy constructor of this class // to make sure we copy all of the string values, but we can't copy the // rhs.m_argv into m_argv since it will point to the "const char *" c // strings in rhs.m_args. We need to copy the string list and update our // own m_argv appropriately. //---------------------------------------------------------------------- Args::Args (const Args &rhs) : m_args (rhs.m_args), m_argv (), m_args_quote_char(rhs.m_args_quote_char) { UpdateArgvFromArgs(); } //---------------------------------------------------------------------- // We have to be very careful on the copy constructor of this class // to make sure we copy all of the string values, but we can't copy the // rhs.m_argv into m_argv since it will point to the "const char *" c // strings in rhs.m_args. We need to copy the string list and update our // own m_argv appropriately. //---------------------------------------------------------------------- const Args & Args::operator= (const Args &rhs) { // Make sure we aren't assigning to self if (this != &rhs) { m_args = rhs.m_args; m_args_quote_char = rhs.m_args_quote_char; UpdateArgvFromArgs(); } return *this; } //---------------------------------------------------------------------- // Destructor //---------------------------------------------------------------------- Args::~Args () { } void Args::Dump (Stream *s) { const size_t argc = m_argv.size(); for (size_t i=0; i<argc; ++i) { s->Indent(); const char *arg_cstr = m_argv[i]; if (arg_cstr) s->Printf("argv[%zi]=\"%s\"\n", i, arg_cstr); else s->Printf("argv[%zi]=NULL\n", i); } s->EOL(); } bool Args::GetCommandString (std::string &command) const { command.clear(); const size_t argc = GetArgumentCount(); for (size_t i=0; i<argc; ++i) { if (i > 0) command += ' '; command += m_argv[i]; } return argc > 0; } bool Args::GetQuotedCommandString (std::string &command) const { command.clear (); const size_t argc = GetArgumentCount(); for (size_t i = 0; i < argc; ++i) { if (i > 0) command.append (1, ' '); char quote_char = GetArgumentQuoteCharAtIndex(i); if (quote_char) { command.append (1, quote_char); command.append (m_argv[i]); command.append (1, quote_char); } else command.append (m_argv[i]); } return argc > 0; } void Args::SetCommandString (const char *command, size_t len) { // Use std::string to make sure we get a NULL terminated string we can use // as "command" could point to a string within a large string.... std::string null_terminated_command(command, len); SetCommandString(null_terminated_command.c_str()); } void Args::SetCommandString (const char *command) { m_args.clear(); m_argv.clear(); m_args_quote_char.clear(); if (command && command[0]) { static const char *k_space_separators = " \t"; static const char *k_space_separators_with_slash_and_quotes = " \t \\'\""; const char *arg_end = NULL; const char *arg_pos; for (arg_pos = command; arg_pos && arg_pos[0]; arg_pos = arg_end) { // Skip any leading space separators const char *arg_start = ::strspn (arg_pos, k_space_separators) + arg_pos; // If there were only space separators to the end of the line, then // we're done. if (*arg_start == '\0') break; // Arguments can be split into multiple discontiguous pieces, // for example: // "Hello ""World" // this would result in a single argument "Hello World" (without/ // the quotes) since the quotes would be removed and there is // not space between the strings. So we need to keep track of the // current start of each argument piece in "arg_piece_start" const char *arg_piece_start = arg_start; arg_pos = arg_piece_start; std::string arg; // Since we can have multiple quotes that form a single command // in a command like: "Hello "world'!' (which will make a single // argument "Hello world!") we remember the first quote character // we encounter and use that for the quote character. char first_quote_char = '\0'; char quote_char = '\0'; bool arg_complete = false; do { arg_end = ::strcspn (arg_pos, k_space_separators_with_slash_and_quotes) + arg_pos; switch (arg_end[0]) { default: assert (!"Unhandled case statement, we must handle this..."); break; case '\0': // End of C string if (arg_piece_start && arg_piece_start[0]) arg.append (arg_piece_start); arg_complete = true; break; case '\\': // Backslash character switch (arg_end[1]) { case '\0': arg.append (arg_piece_start); ++arg_end; arg_complete = true; break; default: if (quote_char == '\0') { arg.append (arg_piece_start, arg_end - arg_piece_start); if (arg_end[1] != '\0') { arg.append (arg_end + 1, 1); arg_pos = arg_end + 2; arg_piece_start = arg_pos; } } else arg_pos = arg_end + 2; break; } break; case '"': case '\'': case '`': // Quote characters if (quote_char) { // We found a quote character while inside a quoted // character argument. If it matches our current quote // character, this ends the effect of the quotes. If it // doesn't we ignore it. if (quote_char == arg_end[0]) { arg.append (arg_piece_start, arg_end - arg_piece_start); // Clear the quote character and let parsing // continue (we need to watch for things like: // "Hello ""World" // "Hello "World // "Hello "'World' // All of which will result in a single argument "Hello World" quote_char = '\0'; // Note that we are no longer inside quotes arg_pos = arg_end + 1; // Skip the quote character arg_piece_start = arg_pos; // Note we are starting from later in the string } else { // different quote, skip it and keep going arg_pos = arg_end + 1; } } else { // We found the start of a quote scope. // Make sure there isn't a string that precedes // the start of a quote scope like: // Hello" World" // If so, then add the "Hello" to the arg if (arg_end > arg_piece_start) arg.append (arg_piece_start, arg_end - arg_piece_start); // Enter into a quote scope quote_char = arg_end[0]; if (first_quote_char == '\0') first_quote_char = quote_char; arg_pos = arg_end; ++arg_pos; // Skip the quote character arg_piece_start = arg_pos; // Note we are starting from later in the string // Skip till the next quote character const char *end_quote = ::strchr (arg_piece_start, quote_char); while (end_quote && end_quote[-1] == '\\') { // Don't skip the quote character if it is // preceded by a '\' character end_quote = ::strchr (end_quote + 1, quote_char); } if (end_quote) { if (end_quote > arg_piece_start) arg.append (arg_piece_start, end_quote - arg_piece_start); // If the next character is a space or the end of // string, this argument is complete... if (end_quote[1] == ' ' || end_quote[1] == '\t' || end_quote[1] == '\0') { arg_complete = true; arg_end = end_quote + 1; } else { arg_pos = end_quote + 1; arg_piece_start = arg_pos; } quote_char = '\0'; } else { // Consume the rest of the string as there was no terminating quote arg.append(arg_piece_start); arg_end = arg_piece_start + strlen(arg_piece_start); arg_complete = true; } } break; case ' ': case '\t': if (quote_char) { // We are currently processing a quoted character and found // a space character, skip any spaces and keep trying to find // the end of the argument. arg_pos = ::strspn (arg_end, k_space_separators) + arg_end; } else { // We are not inside any quotes, we just found a space after an // argument if (arg_end > arg_piece_start) arg.append (arg_piece_start, arg_end - arg_piece_start); arg_complete = true; } break; } } while (!arg_complete); m_args.push_back(arg); m_args_quote_char.push_back (first_quote_char); } UpdateArgvFromArgs(); } } void Args::UpdateArgsAfterOptionParsing() { // Now m_argv might be out of date with m_args, so we need to fix that arg_cstr_collection::const_iterator argv_pos, argv_end = m_argv.end(); arg_sstr_collection::iterator args_pos; arg_quote_char_collection::iterator quotes_pos; for (argv_pos = m_argv.begin(), args_pos = m_args.begin(), quotes_pos = m_args_quote_char.begin(); argv_pos != argv_end && args_pos != m_args.end(); ++argv_pos) { const char *argv_cstr = *argv_pos; if (argv_cstr == NULL) break; while (args_pos != m_args.end()) { const char *args_cstr = args_pos->c_str(); if (args_cstr == argv_cstr) { // We found the argument that matches the C string in the // vector, so we can now look for the next one ++args_pos; ++quotes_pos; break; } else { quotes_pos = m_args_quote_char.erase (quotes_pos); args_pos = m_args.erase (args_pos); } } } if (args_pos != m_args.end()) m_args.erase (args_pos, m_args.end()); if (quotes_pos != m_args_quote_char.end()) m_args_quote_char.erase (quotes_pos, m_args_quote_char.end()); } void Args::UpdateArgvFromArgs() { m_argv.clear(); arg_sstr_collection::const_iterator pos, end = m_args.end(); for (pos = m_args.begin(); pos != end; ++pos) m_argv.push_back(pos->c_str()); m_argv.push_back(NULL); // Make sure we have enough arg quote chars in the array if (m_args_quote_char.size() < m_args.size()) m_args_quote_char.resize (m_argv.size()); } size_t Args::GetArgumentCount() const { if (m_argv.empty()) return 0; return m_argv.size() - 1; } const char * Args::GetArgumentAtIndex (size_t idx) const { if (idx < m_argv.size()) return m_argv[idx]; return NULL; } char Args::GetArgumentQuoteCharAtIndex (size_t idx) const { if (idx < m_args_quote_char.size()) return m_args_quote_char[idx]; return '\0'; } char ** Args::GetArgumentVector() { if (!m_argv.empty()) return (char **)&m_argv[0]; return NULL; } const char ** Args::GetConstArgumentVector() const { if (!m_argv.empty()) return (const char **)&m_argv[0]; return NULL; } void Args::Shift () { // Don't pop the last NULL terminator from the argv array if (m_argv.size() > 1) { m_argv.erase(m_argv.begin()); m_args.pop_front(); if (!m_args_quote_char.empty()) m_args_quote_char.erase(m_args_quote_char.begin()); } } const char * Args::Unshift (const char *arg_cstr, char quote_char) { m_args.push_front(arg_cstr); m_argv.insert(m_argv.begin(), m_args.front().c_str()); m_args_quote_char.insert(m_args_quote_char.begin(), quote_char); return GetArgumentAtIndex (0); } void Args::AppendArguments (const Args &rhs) { const size_t rhs_argc = rhs.GetArgumentCount(); for (size_t i=0; i<rhs_argc; ++i) AppendArgument(rhs.GetArgumentAtIndex(i)); } void Args::AppendArguments (const char **argv) { if (argv) { for (uint32_t i=0; argv[i]; ++i) AppendArgument(argv[i]); } } const char * Args::AppendArgument (const char *arg_cstr, char quote_char) { return InsertArgumentAtIndex (GetArgumentCount(), arg_cstr, quote_char); } const char * Args::InsertArgumentAtIndex (size_t idx, const char *arg_cstr, char quote_char) { // Since we are using a std::list to hold onto the copied C string and // we don't have direct access to the elements, we have to iterate to // find the value. arg_sstr_collection::iterator pos, end = m_args.end(); size_t i = idx; for (pos = m_args.begin(); i > 0 && pos != end; ++pos) --i; pos = m_args.insert(pos, arg_cstr); if (idx >= m_args_quote_char.size()) { m_args_quote_char.resize(idx + 1); m_args_quote_char[idx] = quote_char; } else m_args_quote_char.insert(m_args_quote_char.begin() + idx, quote_char); UpdateArgvFromArgs(); return GetArgumentAtIndex(idx); } const char * Args::ReplaceArgumentAtIndex (size_t idx, const char *arg_cstr, char quote_char) { // Since we are using a std::list to hold onto the copied C string and // we don't have direct access to the elements, we have to iterate to // find the value. arg_sstr_collection::iterator pos, end = m_args.end(); size_t i = idx; for (pos = m_args.begin(); i > 0 && pos != end; ++pos) --i; if (pos != end) { pos->assign(arg_cstr); assert(idx < m_argv.size() - 1); m_argv[idx] = pos->c_str(); if (idx >= m_args_quote_char.size()) m_args_quote_char.resize(idx + 1); m_args_quote_char[idx] = quote_char; return GetArgumentAtIndex(idx); } return NULL; } void Args::DeleteArgumentAtIndex (size_t idx) { // Since we are using a std::list to hold onto the copied C string and // we don't have direct access to the elements, we have to iterate to // find the value. arg_sstr_collection::iterator pos, end = m_args.end(); size_t i = idx; for (pos = m_args.begin(); i > 0 && pos != end; ++pos) --i; if (pos != end) { m_args.erase (pos); assert(idx < m_argv.size() - 1); m_argv.erase(m_argv.begin() + idx); if (idx < m_args_quote_char.size()) m_args_quote_char.erase(m_args_quote_char.begin() + idx); } } void Args::SetArguments (size_t argc, const char **argv) { // m_argv will be rebuilt in UpdateArgvFromArgs() below, so there is // no need to clear it here. m_args.clear(); m_args_quote_char.clear(); // First copy each string for (size_t i=0; i<argc; ++i) { m_args.push_back (argv[i]); if ((argv[i][0] == '\'') || (argv[i][0] == '"') || (argv[i][0] == '`')) m_args_quote_char.push_back (argv[i][0]); else m_args_quote_char.push_back ('\0'); } UpdateArgvFromArgs(); } void Args::SetArguments (const char **argv) { // m_argv will be rebuilt in UpdateArgvFromArgs() below, so there is // no need to clear it here. m_args.clear(); m_args_quote_char.clear(); if (argv) { // First copy each string for (size_t i=0; argv[i]; ++i) { m_args.push_back (argv[i]); if ((argv[i][0] == '\'') || (argv[i][0] == '"') || (argv[i][0] == '`')) m_args_quote_char.push_back (argv[i][0]); else m_args_quote_char.push_back ('\0'); } } UpdateArgvFromArgs(); } Error Args::ParseOptions (Options &options) { StreamString sstr; Error error; struct option *long_options = options.GetLongOptions(); if (long_options == NULL) { error.SetErrorStringWithFormat("invalid long options"); return error; } for (int i=0; long_options[i].name != NULL; ++i) { if (long_options[i].flag == NULL) { if (isprint8(long_options[i].val)) { sstr << (char)long_options[i].val; switch (long_options[i].has_arg) { default: case no_argument: break; case required_argument: sstr << ':'; break; case optional_argument: sstr << "::"; break; } } } } #ifdef __GLIBC__ optind = 0; #else optreset = 1; optind = 1; #endif int val; while (1) { int long_options_index = -1; val = ::getopt_long_only(GetArgumentCount(), GetArgumentVector(), sstr.GetData(), long_options, &long_options_index); if (val == -1) break; // Did we get an error? if (val == '?') { error.SetErrorStringWithFormat("unknown or ambiguous option"); break; } // The option auto-set itself if (val == 0) continue; ((Options *) &options)->OptionSeen (val); // Lookup the long option index if (long_options_index == -1) { for (int i=0; long_options[i].name || long_options[i].has_arg || long_options[i].flag || long_options[i].val; ++i) { if (long_options[i].val == val) { long_options_index = i; break; } } } // Call the callback with the option if (long_options_index >= 0) { error = options.SetOptionValue(long_options_index, long_options[long_options_index].has_arg == no_argument ? NULL : optarg); } else { error.SetErrorStringWithFormat("invalid option with value '%i'", val); } if (error.Fail()) break; } // Update our ARGV now that get options has consumed all the options m_argv.erase(m_argv.begin(), m_argv.begin() + optind); UpdateArgsAfterOptionParsing (); return error; } void Args::Clear () { m_args.clear (); m_argv.clear (); m_args_quote_char.clear(); } int32_t Args::StringToSInt32 (const char *s, int32_t fail_value, int base, bool *success_ptr) { if (s && s[0]) { char *end = NULL; const long sval = ::strtol (s, &end, base); if (*end == '\0') { if (success_ptr) *success_ptr = ((sval <= INT32_MAX) && (sval >= INT32_MIN)); return (int32_t)sval; // All characters were used, return the result } } if (success_ptr) *success_ptr = false; return fail_value; } uint32_t Args::StringToUInt32 (const char *s, uint32_t fail_value, int base, bool *success_ptr) { if (s && s[0]) { char *end = NULL; const unsigned long uval = ::strtoul (s, &end, base); if (*end == '\0') { if (success_ptr) *success_ptr = (uval <= UINT32_MAX); return (uint32_t)uval; // All characters were used, return the result } } if (success_ptr) *success_ptr = false; return fail_value; } int64_t Args::StringToSInt64 (const char *s, int64_t fail_value, int base, bool *success_ptr) { if (s && s[0]) { char *end = NULL; int64_t uval = ::strtoll (s, &end, base); if (*end == '\0') { if (success_ptr) *success_ptr = true; return uval; // All characters were used, return the result } } if (success_ptr) *success_ptr = false; return fail_value; } uint64_t Args::StringToUInt64 (const char *s, uint64_t fail_value, int base, bool *success_ptr) { if (s && s[0]) { char *end = NULL; uint64_t uval = ::strtoull (s, &end, base); if (*end == '\0') { if (success_ptr) *success_ptr = true; return uval; // All characters were used, return the result } } if (success_ptr) *success_ptr = false; return fail_value; } lldb::addr_t Args::StringToAddress (const ExecutionContext *exe_ctx, const char *s, lldb::addr_t fail_value, Error *error_ptr) { bool error_set = false; if (s && s[0]) { char *end = NULL; lldb::addr_t addr = ::strtoull (s, &end, 0); if (*end == '\0') { if (error_ptr) error_ptr->Clear(); return addr; // All characters were used, return the result } // Try base 16 with no prefix... addr = ::strtoull (s, &end, 16); if (*end == '\0') { if (error_ptr) error_ptr->Clear(); return addr; // All characters were used, return the result } if (exe_ctx) { Target *target = exe_ctx->GetTargetPtr(); if (target) { lldb::ValueObjectSP valobj_sp; EvaluateExpressionOptions options; options.SetCoerceToId(false); options.SetUnwindOnError(true); options.SetKeepInMemory(false); options.SetRunOthers(true); ExecutionResults expr_result = target->EvaluateExpression(s, exe_ctx->GetFramePtr(), valobj_sp, options); bool success = false; if (expr_result == eExecutionCompleted) { // Get the address to watch. addr = valobj_sp->GetValueAsUnsigned(fail_value, &success); if (success) { if (error_ptr) error_ptr->Clear(); return addr; } else { if (error_ptr) { error_set = true; error_ptr->SetErrorStringWithFormat("address expression \"%s\" resulted in a value whose type can't be converted to an address: %s", s, valobj_sp->GetTypeName().GetCString()); } } } else { // Since the compiler can't handle things like "main + 12" we should // try to do this for now. The compliler doesn't like adding offsets // to function pointer types. static RegularExpression g_symbol_plus_offset_regex("^(.*)([-\\+])[[:space:]]*(0x[0-9A-Fa-f]+|[0-9]+)[[:space:]]*$"); RegularExpression::Match regex_match(3); if (g_symbol_plus_offset_regex.Execute(s, ®ex_match)) { uint64_t offset = 0; bool add = true; std::string name; std::string str; if (regex_match.GetMatchAtIndex(s, 1, name)) { if (regex_match.GetMatchAtIndex(s, 2, str)) { add = str[0] == '+'; if (regex_match.GetMatchAtIndex(s, 3, str)) { offset = Args::StringToUInt64(str.c_str(), 0, 0, &success); if (success) { Error error; addr = StringToAddress (exe_ctx, name.c_str(), LLDB_INVALID_ADDRESS, &error); if (addr != LLDB_INVALID_ADDRESS) { if (add) return addr + offset; else return addr - offset; } } } } } } if (error_ptr) { error_set = true; error_ptr->SetErrorStringWithFormat("address expression \"%s\" evaluation failed", s); } } } } } if (error_ptr) { if (!error_set) error_ptr->SetErrorStringWithFormat("invalid address expression \"%s\"", s); } return fail_value; } const char * Args::StripSpaces (std::string &s, bool leading, bool trailing, bool return_null_if_empty) { static const char *k_white_space = " \t\v"; if (!s.empty()) { if (leading) { size_t pos = s.find_first_not_of (k_white_space); if (pos == std::string::npos) s.clear(); else if (pos > 0) s.erase(0, pos); } if (trailing) { size_t rpos = s.find_last_not_of(k_white_space); if (rpos != std::string::npos && rpos + 1 < s.size()) s.erase(rpos + 1); } } if (return_null_if_empty && s.empty()) return NULL; return s.c_str(); } bool Args::StringToBoolean (const char *s, bool fail_value, bool *success_ptr) { if (s && s[0]) { if (::strcasecmp (s, "false") == 0 || ::strcasecmp (s, "off") == 0 || ::strcasecmp (s, "no") == 0 || ::strcmp (s, "0") == 0) { if (success_ptr) *success_ptr = true; return false; } else if (::strcasecmp (s, "true") == 0 || ::strcasecmp (s, "on") == 0 || ::strcasecmp (s, "yes") == 0 || ::strcmp (s, "1") == 0) { if (success_ptr) *success_ptr = true; return true; } } if (success_ptr) *success_ptr = false; return fail_value; } const char * Args::StringToVersion (const char *s, uint32_t &major, uint32_t &minor, uint32_t &update) { major = UINT32_MAX; minor = UINT32_MAX; update = UINT32_MAX; if (s && s[0]) { char *pos = NULL; unsigned long uval32 = ::strtoul (s, &pos, 0); if (pos == s) return s; major = uval32; if (*pos == '\0') { return pos; // Decoded major and got end of string } else if (*pos == '.') { const char *minor_cstr = pos + 1; uval32 = ::strtoul (minor_cstr, &pos, 0); if (pos == minor_cstr) return pos; // Didn't get any digits for the minor version... minor = uval32; if (*pos == '.') { const char *update_cstr = pos + 1; uval32 = ::strtoul (update_cstr, &pos, 0); if (pos == update_cstr) return pos; update = uval32; } return pos; } } return 0; } const char * Args::GetShellSafeArgument (const char *unsafe_arg, std::string &safe_arg) { safe_arg.assign (unsafe_arg); size_t prev_pos = 0; while (prev_pos < safe_arg.size()) { // Escape spaces and quotes size_t pos = safe_arg.find_first_of(" '\"", prev_pos); if (pos != std::string::npos) { safe_arg.insert (pos, 1, '\\'); prev_pos = pos + 2; } else break; } return safe_arg.c_str(); } int64_t Args::StringToOptionEnum (const char *s, OptionEnumValueElement *enum_values, int32_t fail_value, Error &error) { if (enum_values) { if (s && s[0]) { for (int i = 0; enum_values[i].string_value != NULL ; i++) { if (strstr(enum_values[i].string_value, s) == enum_values[i].string_value) { error.Clear(); return enum_values[i].value; } } } StreamString strm; strm.PutCString ("invalid enumeration value, valid values are: "); for (int i = 0; enum_values[i].string_value != NULL; i++) { strm.Printf ("%s\"%s\"", i > 0 ? ", " : "", enum_values[i].string_value); } error.SetErrorString(strm.GetData()); } else { error.SetErrorString ("invalid enumeration argument"); } return fail_value; } ScriptLanguage Args::StringToScriptLanguage (const char *s, ScriptLanguage fail_value, bool *success_ptr) { if (s && s[0]) { if ((::strcasecmp (s, "python") == 0) || (::strcasecmp (s, "default") == 0 && eScriptLanguagePython == eScriptLanguageDefault)) { if (success_ptr) *success_ptr = true; return eScriptLanguagePython; } if (::strcasecmp (s, "none")) { if (success_ptr) *success_ptr = true; return eScriptLanguageNone; } } if (success_ptr) *success_ptr = false; return fail_value; } Error Args::StringToFormat ( const char *s, lldb::Format &format, size_t *byte_size_ptr ) { format = eFormatInvalid; Error error; if (s && s[0]) { if (byte_size_ptr) { if (isdigit (s[0])) { char *format_char = NULL; unsigned long byte_size = ::strtoul (s, &format_char, 0); if (byte_size != ULONG_MAX) *byte_size_ptr = byte_size; s = format_char; } else *byte_size_ptr = 0; } const bool partial_match_ok = true; if (!FormatManager::GetFormatFromCString (s, partial_match_ok, format)) { StreamString error_strm; error_strm.Printf ("Invalid format character or name '%s'. Valid values are:\n", s); for (Format f = eFormatDefault; f < kNumFormats; f = Format(f+1)) { char format_char = FormatManager::GetFormatAsFormatChar(f); if (format_char) error_strm.Printf ("'%c' or ", format_char); error_strm.Printf ("\"%s\"", FormatManager::GetFormatAsCString(f)); error_strm.EOL(); } if (byte_size_ptr) error_strm.PutCString ("An optional byte size can precede the format character.\n"); error.SetErrorString(error_strm.GetString().c_str()); } if (error.Fail()) return error; } else { error.SetErrorStringWithFormat("%s option string", s ? "empty" : "invalid"); } return error; } lldb::Encoding Args::StringToEncoding (const char *s, lldb::Encoding fail_value) { if (s && s[0]) { if (strcmp(s, "uint") == 0) return eEncodingUint; else if (strcmp(s, "sint") == 0) return eEncodingSint; else if (strcmp(s, "ieee754") == 0) return eEncodingIEEE754; else if (strcmp(s, "vector") == 0) return eEncodingVector; } return fail_value; } uint32_t Args::StringToGenericRegister (const char *s) { if (s && s[0]) { if (strcmp(s, "pc") == 0) return LLDB_REGNUM_GENERIC_PC; else if (strcmp(s, "sp") == 0) return LLDB_REGNUM_GENERIC_SP; else if (strcmp(s, "fp") == 0) return LLDB_REGNUM_GENERIC_FP; else if (strcmp(s, "ra") == 0) return LLDB_REGNUM_GENERIC_RA; else if (strcmp(s, "flags") == 0) return LLDB_REGNUM_GENERIC_FLAGS; else if (strncmp(s, "arg", 3) == 0) { if (s[3] && s[4] == '\0') { switch (s[3]) { case '1': return LLDB_REGNUM_GENERIC_ARG1; case '2': return LLDB_REGNUM_GENERIC_ARG2; case '3': return LLDB_REGNUM_GENERIC_ARG3; case '4': return LLDB_REGNUM_GENERIC_ARG4; case '5': return LLDB_REGNUM_GENERIC_ARG5; case '6': return LLDB_REGNUM_GENERIC_ARG6; case '7': return LLDB_REGNUM_GENERIC_ARG7; case '8': return LLDB_REGNUM_GENERIC_ARG8; } } } } return LLDB_INVALID_REGNUM; } void Args::LongestCommonPrefix (std::string &common_prefix) { arg_sstr_collection::iterator pos, end = m_args.end(); pos = m_args.begin(); if (pos == end) common_prefix.clear(); else common_prefix = (*pos); for (++pos; pos != end; ++pos) { size_t new_size = (*pos).size(); // First trim common_prefix if it is longer than the current element: if (common_prefix.size() > new_size) common_prefix.erase (new_size); // Then trim it at the first disparity: for (size_t i = 0; i < common_prefix.size(); i++) { if ((*pos)[i] != common_prefix[i]) { common_prefix.erase(i); break; } } // If we've emptied the common prefix, we're done. if (common_prefix.empty()) break; } } size_t Args::FindArgumentIndexForOption (struct option *long_options, int long_options_index) { char short_buffer[3]; char long_buffer[255]; ::snprintf (short_buffer, sizeof (short_buffer), "-%c", long_options[long_options_index].val); ::snprintf (long_buffer, sizeof (long_buffer), "--%s", long_options[long_options_index].name); size_t end = GetArgumentCount (); size_t idx = 0; while (idx < end) { if ((::strncmp (GetArgumentAtIndex (idx), short_buffer, strlen (short_buffer)) == 0) || (::strncmp (GetArgumentAtIndex (idx), long_buffer, strlen (long_buffer)) == 0)) { return idx; } ++idx; } return end; } bool Args::IsPositionalArgument (const char *arg) { if (arg == NULL) return false; bool is_positional = true; char *cptr = (char *) arg; if (cptr[0] == '%') { ++cptr; while (isdigit (cptr[0])) ++cptr; if (cptr[0] != '\0') is_positional = false; } else is_positional = false; return is_positional; } void Args::ParseAliasOptions (Options &options, CommandReturnObject &result, OptionArgVector *option_arg_vector, std::string &raw_input_string) { StreamString sstr; int i; struct option *long_options = options.GetLongOptions(); if (long_options == NULL) { result.AppendError ("invalid long options"); result.SetStatus (eReturnStatusFailed); return; } for (i = 0; long_options[i].name != NULL; ++i) { if (long_options[i].flag == NULL) { sstr << (char) long_options[i].val; switch (long_options[i].has_arg) { default: case no_argument: break; case required_argument: sstr << ":"; break; case optional_argument: sstr << "::"; break; } } } #ifdef __GLIBC__ optind = 0; #else optreset = 1; optind = 1; #endif int val; while (1) { int long_options_index = -1; val = ::getopt_long_only (GetArgumentCount(), GetArgumentVector(), sstr.GetData(), long_options, &long_options_index); if (val == -1) break; if (val == '?') { result.AppendError ("unknown or ambiguous option"); result.SetStatus (eReturnStatusFailed); break; } if (val == 0) continue; ((Options *) &options)->OptionSeen (val); // Look up the long option index if (long_options_index == -1) { for (int j = 0; long_options[j].name || long_options[j].has_arg || long_options[j].flag || long_options[j].val; ++j) { if (long_options[j].val == val) { long_options_index = j; break; } } } // See if the option takes an argument, and see if one was supplied. if (long_options_index >= 0) { StreamString option_str; option_str.Printf ("-%c", val); switch (long_options[long_options_index].has_arg) { case no_argument: option_arg_vector->push_back (OptionArgPair (std::string (option_str.GetData()), OptionArgValue (no_argument, "<no-argument>"))); result.SetStatus (eReturnStatusSuccessFinishNoResult); break; case required_argument: if (optarg != NULL) { option_arg_vector->push_back (OptionArgPair (std::string (option_str.GetData()), OptionArgValue (required_argument, std::string (optarg)))); result.SetStatus (eReturnStatusSuccessFinishNoResult); } else { result.AppendErrorWithFormat ("Option '%s' is missing argument specifier.\n", option_str.GetData()); result.SetStatus (eReturnStatusFailed); } break; case optional_argument: if (optarg != NULL) { option_arg_vector->push_back (OptionArgPair (std::string (option_str.GetData()), OptionArgValue (optional_argument, std::string (optarg)))); result.SetStatus (eReturnStatusSuccessFinishNoResult); } else { option_arg_vector->push_back (OptionArgPair (std::string (option_str.GetData()), OptionArgValue (optional_argument, "<no-argument>"))); result.SetStatus (eReturnStatusSuccessFinishNoResult); } break; default: result.AppendErrorWithFormat ("error with options table; invalid value in has_arg field for option '%c'.\n", val); result.SetStatus (eReturnStatusFailed); break; } } else { result.AppendErrorWithFormat ("Invalid option with value '%c'.\n", val); result.SetStatus (eReturnStatusFailed); } if (long_options_index >= 0) { // Find option in the argument list; also see if it was supposed to take an argument and if one was // supplied. Remove option (and argument, if given) from the argument list. Also remove them from // the raw_input_string, if one was passed in. size_t idx = FindArgumentIndexForOption (long_options, long_options_index); if (idx < GetArgumentCount()) { if (raw_input_string.size() > 0) { const char *tmp_arg = GetArgumentAtIndex (idx); size_t pos = raw_input_string.find (tmp_arg); if (pos != std::string::npos) raw_input_string.erase (pos, strlen (tmp_arg)); } ReplaceArgumentAtIndex (idx, ""); if ((long_options[long_options_index].has_arg != no_argument) && (optarg != NULL) && (idx+1 < GetArgumentCount()) && (strcmp (optarg, GetArgumentAtIndex(idx+1)) == 0)) { if (raw_input_string.size() > 0) { const char *tmp_arg = GetArgumentAtIndex (idx+1); size_t pos = raw_input_string.find (tmp_arg); if (pos != std::string::npos) raw_input_string.erase (pos, strlen (tmp_arg)); } ReplaceArgumentAtIndex (idx+1, ""); } } } if (!result.Succeeded()) break; } } void Args::ParseArgsForCompletion ( Options &options, OptionElementVector &option_element_vector, uint32_t cursor_index ) { StreamString sstr; struct option *long_options = options.GetLongOptions(); option_element_vector.clear(); if (long_options == NULL) { return; } // Leading : tells getopt to return a : for a missing option argument AND // to suppress error messages. sstr << ":"; for (int i = 0; long_options[i].name != NULL; ++i) { if (long_options[i].flag == NULL) { sstr << (char) long_options[i].val; switch (long_options[i].has_arg) { default: case no_argument: break; case required_argument: sstr << ":"; break; case optional_argument: sstr << "::"; break; } } } #ifdef __GLIBC__ optind = 0; #else optreset = 1; optind = 1; #endif opterr = 0; int val; const OptionDefinition *opt_defs = options.GetDefinitions(); // Fooey... getopt_long_only permutes the GetArgumentVector to move the options to the front. // So we have to build another Arg and pass that to getopt_long_only so it doesn't // change the one we have. std::vector<const char *> dummy_vec (GetArgumentVector(), GetArgumentVector() + GetArgumentCount() + 1); bool failed_once = false; uint32_t dash_dash_pos = -1; while (1) { bool missing_argument = false; int long_options_index = -1; val = ::getopt_long_only (dummy_vec.size() - 1, (char *const *) &dummy_vec.front(), sstr.GetData(), long_options, &long_options_index); if (val == -1) { // When we're completing a "--" which is the last option on line, if (failed_once) break; failed_once = true; // If this is a bare "--" we mark it as such so we can complete it successfully later. // Handling the "--" is a little tricky, since that may mean end of options or arguments, or the // user might want to complete options by long name. I make this work by checking whether the // cursor is in the "--" argument, and if so I assume we're completing the long option, otherwise // I let it pass to getopt_long_only which will terminate the option parsing. // Note, in either case we continue parsing the line so we can figure out what other options // were passed. This will be useful when we come to restricting completions based on what other // options we've seen on the line. if (optind < dummy_vec.size() - 1 && (strcmp (dummy_vec[optind-1], "--") == 0)) { dash_dash_pos = optind - 1; if (optind - 1 == cursor_index) { option_element_vector.push_back (OptionArgElement (OptionArgElement::eBareDoubleDash, optind - 1, OptionArgElement::eBareDoubleDash)); continue; } else break; } else break; } else if (val == '?') { option_element_vector.push_back (OptionArgElement (OptionArgElement::eUnrecognizedArg, optind - 1, OptionArgElement::eUnrecognizedArg)); continue; } else if (val == 0) { continue; } else if (val == ':') { // This is a missing argument. val = optopt; missing_argument = true; } ((Options *) &options)->OptionSeen (val); // Look up the long option index if (long_options_index == -1) { for (int j = 0; long_options[j].name || long_options[j].has_arg || long_options[j].flag || long_options[j].val; ++j) { if (long_options[j].val == val) { long_options_index = j; break; } } } // See if the option takes an argument, and see if one was supplied. if (long_options_index >= 0) { int opt_defs_index = -1; for (int i = 0; ; i++) { if (opt_defs[i].short_option == 0) break; else if (opt_defs[i].short_option == val) { opt_defs_index = i; break; } } switch (long_options[long_options_index].has_arg) { case no_argument: option_element_vector.push_back (OptionArgElement (opt_defs_index, optind - 1, 0)); break; case required_argument: if (optarg != NULL) { int arg_index; if (missing_argument) arg_index = -1; else arg_index = optind - 1; option_element_vector.push_back (OptionArgElement (opt_defs_index, optind - 2, arg_index)); } else { option_element_vector.push_back (OptionArgElement (opt_defs_index, optind - 1, -1)); } break; case optional_argument: if (optarg != NULL) { option_element_vector.push_back (OptionArgElement (opt_defs_index, optind - 2, optind - 1)); } else { option_element_vector.push_back (OptionArgElement (opt_defs_index, optind - 2, optind - 1)); } break; default: // The options table is messed up. Here we'll just continue option_element_vector.push_back (OptionArgElement (OptionArgElement::eUnrecognizedArg, optind - 1, OptionArgElement::eUnrecognizedArg)); break; } } else { option_element_vector.push_back (OptionArgElement (OptionArgElement::eUnrecognizedArg, optind - 1, OptionArgElement::eUnrecognizedArg)); } } // Finally we have to handle the case where the cursor index points at a single "-". We want to mark that in // the option_element_vector, but only if it is not after the "--". But it turns out that getopt_long_only just ignores // an isolated "-". So we have to look it up by hand here. We only care if it is AT the cursor position. if ((dash_dash_pos == -1 || cursor_index < dash_dash_pos) && strcmp (GetArgumentAtIndex(cursor_index), "-") == 0) { option_element_vector.push_back (OptionArgElement (OptionArgElement::eBareDash, cursor_index, OptionArgElement::eBareDash)); } } void Args::EncodeEscapeSequences (const char *src, std::string &dst) { dst.clear(); if (src) { for (const char *p = src; *p != '\0'; ++p) { size_t non_special_chars = ::strcspn (p, "\\"); if (non_special_chars > 0) { dst.append(p, non_special_chars); p += non_special_chars; if (*p == '\0') break; } if (*p == '\\') { ++p; // skip the slash switch (*p) { case 'a' : dst.append(1, '\a'); break; case 'b' : dst.append(1, '\b'); break; case 'f' : dst.append(1, '\f'); break; case 'n' : dst.append(1, '\n'); break; case 'r' : dst.append(1, '\r'); break; case 't' : dst.append(1, '\t'); break; case 'v' : dst.append(1, '\v'); break; case '\\': dst.append(1, '\\'); break; case '\'': dst.append(1, '\''); break; case '"' : dst.append(1, '"'); break; case '0' : // 1 to 3 octal chars { // Make a string that can hold onto the initial zero char, // up to 3 octal digits, and a terminating NULL. char oct_str[5] = { '\0', '\0', '\0', '\0', '\0' }; int i; for (i=0; (p[i] >= '0' && p[i] <= '7') && i<4; ++i) oct_str[i] = p[i]; // We don't want to consume the last octal character since // the main for loop will do this for us, so we advance p by // one less than i (even if i is zero) p += i - 1; unsigned long octal_value = ::strtoul (oct_str, NULL, 8); if (octal_value <= UINT8_MAX) { dst.append(1, (char)octal_value); } } break; case 'x': // hex number in the format if (isxdigit(p[1])) { ++p; // Skip the 'x' // Make a string that can hold onto two hex chars plus a // NULL terminator char hex_str[3] = { *p, '\0', '\0' }; if (isxdigit(p[1])) { ++p; // Skip the first of the two hex chars hex_str[1] = *p; } unsigned long hex_value = strtoul (hex_str, NULL, 16); if (hex_value <= UINT8_MAX) dst.append (1, (char)hex_value); } else { dst.append(1, 'x'); } break; default: // Just desensitize any other character by just printing what // came after the '\' dst.append(1, *p); break; } } } } } void Args::ExpandEscapedCharacters (const char *src, std::string &dst) { dst.clear(); if (src) { for (const char *p = src; *p != '\0'; ++p) { if (isprint8(*p)) dst.append(1, *p); else { switch (*p) { case '\a': dst.append("\\a"); break; case '\b': dst.append("\\b"); break; case '\f': dst.append("\\f"); break; case '\n': dst.append("\\n"); break; case '\r': dst.append("\\r"); break; case '\t': dst.append("\\t"); break; case '\v': dst.append("\\v"); break; case '\'': dst.append("\\'"); break; case '"': dst.append("\\\""); break; case '\\': dst.append("\\\\"); break; default: { // Just encode as octal dst.append("\\0"); char octal_str[32]; snprintf(octal_str, sizeof(octal_str), "%o", *p); dst.append(octal_str); } break; } } } } }